锌溴液流电池储能技术研究和应用进展

doi:10.3969/j.issn.2095-4239.2013.01.003

储能科学与技术 ›› 2013, Vol. 2 ›› Issue (1): 35-41.doi: 10.3969/j.issn.2095-4239.2013.01.003

锌溴液流电池储能技术研究和应用进展

孟琳

北京百能汇通科技股份有限公司,北京 101102

收稿日期:2012-11-12 修回日期:2012-11-19 出版日期:2013-02-19 发布日期:2013-02-19

Recent progress in zinc-bromine flow battery energy storage technologies

MENG Lin

Beijing ZBEST Technology Co., Ltd.,Beijing 101102,China

Received:2012-11-12 Revised:2012-11-19 Online:2013-02-19 Published:2013-02-19

摘要/Abstract

摘要： 以活性物质溴化锌为电解液主要成分的锌溴液流电池,其电极及隔膜材料均由塑料构成,具有低成本,长寿命,绿色环保等特点,适合进行大规模的电能存储,在可再生能源接入,分布式发电及智能电网等领域有着巨大的发展潜力.本文介绍了锌溴液流电池的技术原理与组成,分析了其技术特点,概述了目前的研究开发状况,对未来的前景进行了展望,指出进行关键材料的自主研发及批量化生产,优化电堆及系统的结构,控制产品生产工艺质量等是未来研究工作的重点.

关键词: 锌溴液流电池, 分布式发电, 微孔隔膜, 智能电网

Abstract: The use of zinc-bromine flow battery technologies has a number of advantages for large-scale electrical energy storage applications including low cost, long service life and environmental friendliness. It has a huge potential for a high extent of renewable energy penetration, distributed generation and smart grid. This paper briefly introduces the principle and component configuration of zinc-bromine flow batteries, analyzes their characteristics, and reviews recent state-of-art development in the area. Finally, recommendations for future research are proposed.

Key words: zinc-bromine flow battery, distributed generation, micro-porous separator, smart grid

中图分类号:

TM911

孟琳. 锌溴液流电池储能技术研究和应用进展[J]. 储能科学与技术, 2013, 2(1): 35-41.

MENG Lin. Recent progress in zinc-bromine flow battery energy storage technologies[J]. Energy Storage Science and Technology, 2013, 2(1): 35-41.

参考文献

[1] 全国工商联新能源商会储能专业委员会. 储能产业研究白皮书2011[R]. 北京:2011.
[2] Energy storage for power grids and electric transportation:A technology assessment [EB/OL]. [2012-03-27].http://www.fas.org/sgp/crs/misc/R42455.pdf.
[3] Francisco Díaz-González,Andreas Sumper. A review of energy storage technologies for wind power applications[J]. Renewable and Sustainable Energy Reviews ,2012,16:2154-2171.
[4] Dominic D,Banham-Hall,Gareth A,Taylo. Flow batteries for enhancing wind power integration[J]. IEEE Transactions on Power Systems ,2012,27(3):1690-1697.
[5] Gyuk I,Kamath H. EPRI-DOE handbook of energy storage for transmission and distribution applications[R]. Washington DC:DOE & EPRI,2003.
[6] Ponce de León C,Frias-Ferrer A. Redox flow cells for energy conversion[J]. Journal of Power Source ,2006,160:716-732.
[7] 戴维·林登,托马斯 B 雷迪. 电池手册[M]. 3版. 北京:化学工业出版社,2007.
[8] Peter J L,Bjorn Jonshagen. The zinc-bromine battery system for utility and remote area applications[J]. Power Engineering Journal ,1999,13(3):142-148.
[9] Evans T I,White R E. A review for the mathematic modeling of zinc/bromine flow cell and battery[J]. Journal of Electrochemical Society ,1987,134(11):2725-2733.
[10] Lee J,Selman J R. Effects of separator and terminal on the current distribution in parallel-plate electrochemical flow reactors[J]. Journal of Electrochemical Society ,1982,129 (8):1670-1678.
[11] Evans T I,White R E. A mathematical model of a zinc/bromine flow cell[J]. Journal of Electrochemical Society ,1987,134(4):866-874.
[12] Charles Arnold Jr. Durability of carbon-plastic electrodes for zinc/bromine storage batteries[R]. California:Sandia Nation Laboratory,1992.
[13] James Bolsted,Phillip Eidler. Proof-of-concept zinc/bromine electric vehicle battery[R]. California:Sandia Nation Laboratory,1991.
[14] Leo A. Status of zinc-bromine battery development at energy research corporation[C]//Energy Conversion Engineering Conference,1989,3:1303-1309.
[15] Carl D J,Peter J L. Carbon coating for an electrode:US,5626986[P]. 1995.
[16] Nicholas J Magnani,Paul C Bulter. Utility battery exploratory technology development program report for FY91[R]. California:Sandia Nation Laboratory 1991.
[17] Bellows R,Einstein H,Grimes P. Development of a circulating zinc-bromine battery Phase I final report[R]. California:Sandia Nation Laboratory,1983.
[18] Pankaj Arora,Zhang Zhengming. Battery separators[J]. Chemical Reviews ,2004,104(10):4419-4462.
[19] Toshinobu Fujii,Yasuo Ando. Secondary battery with ion-exchange porous membrane:US,4824743[P]. 1989.
[20] Phillip Eidler. Developments of zinc/bromine batteries for load-leveling applications:Phase I final report[R]. California:Sandia Nation Laboratory,1999.
[21] Yasho Ando,Toshihiko Ochiai. Electrolyte for zinc-bromine storage batteries:US,4510218[P]. 1985.
[22] Nanch Clark,Philip Eidler. Development of zinc/bromine batteries for load-leveling applications:Phase 2 final report[R]. California:Sandia Nation Laboratory,1999.
[23] Fritz Beck,Paul Retschi. Rechargeable batteries with aqueous electrolytes[J]. Electrochimica Acta ,2000,45:2467-2482.
[24] Palo Alto. Assessment of advanced batteries for energy storage application in deregulated electric utilities[R]. California:EPRI,1998.
[25] Peter J L,Matthews J F. Recent developments in zinc/bromine battery technology at Johnson Controls[C]//IEEE 35th International Power Sources Symposium,1992:88-92.
[26] Peter J L. Demonstrations of ZBB energy storage systems[R]. California:California Energy Commission,2012.
[27] SG_Demo_Project list11-24-09 [EB/OL].[2011-09-24]. http://www.sandia.gov/ess/docs/events_news/FOA36_storagedemos_11-24-09.pdf.
[28] Toshinobu Fujii,Igarashi M. 4MW zinc/bromine battery for electric power for electric power storage[C]//The 24th Intersociety Energy Conversion Engineering Conference,1989,3:1319-1323.
[29] David M Rose,Summer R Ferreira. Initial test results from the Red Flow 5 kW,10 kWh zinc-bromide module,Phase I [R]. California:Sandia Nation Laboratory,2012.

锌溴液流电池储能技术研究和应用进展

Recent progress in zinc-bromine flow battery energy storage technologies

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